Marcin Kwapisz | Simulations | Research Excellence Award

Published on by Technology Scientists

Dr. Marcin Kwapisz | Simulations | Research Excellence Award

Senior Researcher | Czestochowa University of Technology | Poland 

Dr. Marcin Kwapisz is a materials engineering and nondestructive evaluation (NDE) researcher at the Częstochowa University of Technology, specializing in the mechanical behavior of materials under complex loading and in the development of advanced diagnostic technologies for industrial applications. With a portfolio of 30 publications, 74 citations, and an h-index of 5, he has contributed to strengthening scientific understanding of alternate pressing, multiaxial compression, and magnetic-based assessment techniques. His work places particular emphasis on Barkhausen Noise (BN) testing, where he has co-developed robotic and integrated measuring heads that improve the precision, repeatability, and automation of structural integrity evaluation in ferromagnetic materials. Collaborating with over 28 co-authors, Kwapisz engages in cross-disciplinary research bridging materials science, mechanical engineering, sensor technology, and automation, resulting in outputs that support enhanced quality control, reduced failure risk, and greater manufacturing efficiency. Collectively, his research advances modern inspection methodologies and contributes to safer, more reliable, and technologically progressive engineering practices worldwide.

Profiles: Scopus | ORCID | Google Scholar

Featured Publications

1. Knapiński, M., Dyja, H., Kawałek, A., Kwapisz, M., & Koczurkiewicz, B. (2013). Physical simulations of the controlled rolling process of plate X100 with accelerated cooling. Solid State Phenomena, 199, 484–489.
Cited by: 19

2. Dyja, H., Knapiński, M., Kwapisz, M., & Snopek, J. (2011). Physical simulation of controlled rolling and accelerated cooling for ultrafine-grained steel plates. Archives of Metallurgy and Materials, 56, 447–454.
Cited by: 10

3. Kawałek, A., Bajor, T., Kwapisz, M., Sawicki, S., & Borowski, J. (2021). Numerical modeling of the extrusion process of aluminum alloy 6XXX series section. Journal of Chemical Technology & Metallurgy, 56(2).
Cited by: 7

4. Dyja, H., Kwapisz, M., Laber, K., & Knapiński, M. (2011). Analysis of the effect of the tool shape on the stress and strain distribution in the alternate extrusion and multiaxial compression process. Archives of Metallurgy and Materials.
Cited by: 7

5. Rydz, D., Garstka, T., Koczurkiewicz, B., & Kwapisz, M. (2014). Walcowanie blach grubych ze stopu magnezu AZ31. Hutnik, Wiadomości Hutnicze, 81(5).
Cited by: 6

Reza Faraji | Electrical Engineering | Best Researcher Award

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Dr. Reza Faraji | Electrical Engineering | Best Researcher Award

PhD Candidate | University of Science and Culture | Iran

Dr. Reza Faraji is a dedicated PhD candidate in Electrical and Computer Engineering at Islamic Azad University (IAU), with a collaborative affiliation with the University of Science and Culture (USC). His primary area of research is nanoelectronics, with a specialization in Quantum-dot Cellular Automata (QCA) and reversible computing. He earned his Master’s degree in QCA design from USC, where his thesis focused on designing low-power, high-performance digital circuits. Reza’s academic foundation is reinforced by research assistant roles and engagement in advanced nano-circuit projects. His ongoing research includes the design of a Multilayer Reversible ALU (RALU) using Fredkin and HN gates optimized for 6G-enabled IoT systems, and device modeling of AlN/β- and ε-Ga₂O₃ Tri-Gate MOSHEMTs using DFT and TCAD simulations for mm-Wave applications on diamond substrates. These projects aim to advance low-power and high-efficiency architectures for next-generation communication and computation systems. He actively collaborates with Dr. Abdalhossein Rezai (USC) on QCA-based circuit design and with Dr. Amir Amini (IAU, West Tehran Branch) on nanoscale device modeling. Although he has no patents or books published yet, his work shows promise for industrial applications in IoT and semiconductor sectors. Currently, Reza has 5 published documents, 18 citations and an h-index of 3, reflecting the growing impact of his research in the scientific community. His key areas of expertise include QCA, reversible logic, ALU design, nanoscale HEMTs, and energy-efficient digital architectures for 6G and future nanoelectronic systems.

Profiles: Scopus | Google Scholar | ORCID

Featured Publications

1. Faraji-Dana, R., & Chow, Y. L. (2002). The current distribution and AC resistance of a microstrip structure. IEEE Transactions on Microwave Theory and Techniques, 38(9), 1268–1277. 
Cited by: 149

2. Mehdipour, A., Mohammadpour-Aghdam, K., & Faraji-Dana, R. (2007). Complete dispersion analysis of Vivaldi antenna for ultra wideband applications. Progress In Electromagnetics Research, 77, 85–96. 
Cited by: 134

3. Hosseininejad, S. E., Rouhi, K., Neshat, M., Faraji-Dana, R., & Abdolali, A. (2019). Reprogrammable graphene-based metasurface mirror with adaptive focal point for THz imaging. Scientific Reports, 9(1), 2868. 
Cited by: 107

4. Abbas-Azimi, M., Arazm, F., Rashed-Mohassel, J., & Faraji-Dana, R. (2007). Design and optimization of a new 1–18 GHz double ridged guide horn antenna. Journal of Electromagnetic Waves and Applications, 21(4), 501–516. 
Cited by: 76

5. Faraji-Dana, R., & Chow, Y. (1990). Edge condition of the field and AC resistance of a rectangular strip conductor. IEE Proceedings H – Microwaves, Antennas and Propagation, 137(2), 133–140. 
Cited by: 71